Abstract

The snake shed skin has long been used in the Chinese and Indian traditional, folk medicine for various medicinal purposes. Previously it was reported that N. naja shedded skin caused temporary cessation of the estrous cycle. Based on these reviews and reports this work was undertaken to purify, characterize bioactive compound from Naja naja shedded skin and to assess its bioactivity in animal model.

Keywords

Introduction

The estrous cycle of female mice involved four phases: diestrous, metestrous, proestrous and estrous, it lasted for 4-5 days. It is regulated very intricately by endocrine and cytokine circuitry. The short length and less complexity of the estrous cycle in mice made it ideal animal experimental model for study on reproductive cycle, including the effect of anti fertility agents from natural sources.

The female anti fertility drugs generally prescribed by doctors are chemically steroids, available in a combination of estrogen and progestins, also known as oral contraceptive pills. The adverse side effects of the oral contraceptive pills included cardiovascular diseases, venous risk and metabolic disorder like lipoprotein changes, altered insulin response to glucose and prolonged use of those even might lead to endometriosis [1-3]. The nonsteroidal anti fertility drugs e.g. Gonadotropin-releasing hormone analogues (goserelin, leuprolide triptorelin) that are marketed in place of steroidal contraceptive pills also have severe side effects, affecting the central nervous system, associated CNS depression [4]. Hence search of newer alternatives for female contraception from natural products is going on and is still a challenge to scientists’ globally [5,6].

Snake shed skin has long been used in the Chinese traditional medicine for various disorders including malignant sores, such as mammary abscess and tumor, boils, carbuncles, and furuncles. The shedded skins are usually roasted and then used both internally and topically. The snake shed skin considered useful in reducing clouding of the cornea. In Indian traditional, folk and Santhal medicinal system mentioned the use of snake shed skin for reproductive disorders, and previous studies had shown that Naja naja shedded skin influenced rat estrous cycle [7]. However no reports are available regarding the presence of any bioactive compounds in the N. naja shedded skin. The present study was designed to isolate bioactive molecule from N. naja shedded skin and the probable molecular action on female estrous cycle.

Female Swiss albino mice 10-12 weeks old were purchased from approved animal breeders of Maulana Azad College, Kolkata; they were housed in polypropylene cages at temperature (26±2 °C) and light controlled environment (12 h light/dark). All the animals were fed with standard laboratory diet, had free access to food and water ad libidum. Estrous cycle was followed by carrying out vaginal smears daily. Vaginal lavage was performed using approximately 30 μl of 0.9% NaCl, dispensed in the vagina through plastic tip applicator. Cells were collected and studied under microscope to confirm each stage of estrous cycle. Animals showing two consecutive cycles were used for the experimental study. Regulations of the Animal Experimental Ethics Committee were followed, and were in accordance with the guidelines of the Committee for the Purpose of Control and Supervision of Experiments on Animal (CPCSEA) [25/250/2012- AWD], Government of India. Vaginal lavage was observed every 24 h for 5 consecutive days.

Collection of N. naja shedded skin

Fresh Naja naja shedded skins of both sexes were collected from North 24-Parganas of West Bengal, India as per the permission granted by the Ministry of Forests & Wild Life, Govt. of West Bengal, India [2105/WL/4R-l (PI-IX)].

On day 5 following NNSS2 exposure serum 17-β estradiol, progesterone, IL-1β and TNF-α levels were measured by ELISA.

Histopathological studies of NNSS2 treated mice uterus and ovary

On day 5 following NNSS2 exposure uterus and ovaries of mice were isolated and fixed in 10% buffered formalin followed by dehydration, clearing and paraffin embedding. 5 μ sections were stained with haematoxylin-eosin and observed under bright field microscope.

Western immunoblot analysis

Expressions of different proteins (Bax, BCl2, HSP 70, HSP 90, PARP, and β-actin) of uterus and ovary tissue homogenate were analysed by western blot. For preparation of tissue homogenate uterus and ovaries were isolated and placed in cold PBS (pH 7.2). 10% tissue homogenate was prepared in RIPA lysis buffer in the presence of protease inhibitor cocktail. After incubation period of 1 h at 4 °C, it was centrifuged at 12,000 rpm for 30 min (4 °C). The supernatant was collected and stored in -20 °C for future use. Equal concentration and volume of cellular protein samples were run in 12.5% SDS PAGE and transferred to nitrocellulose membrane in an immunoblot apparatus using transfer buffer (193 mM Glycine, 25 mM Tris and 20% methanol) and were blocked using 5% BSA in TBST (Tris buffered saline-Tween 20) for 2 h. The membrane was next incubated with respective primary antibody diluted with TBST containing 0.3% BSA and kept for overnight. Next day, the membrane was washed with TBS (Tris buffered saline) to remove unbound primary antibodies and next incubated with respective secondary antibody (alkaline phosphatase conjugated). The membrane was washed with TBS and colour was developed using NBT-BCIP mix in dark. Finally membranes were scanned for future documentation. After westernblot, each bands (except PARP, as it was cleaved after treatment) were analyzed through ImageJ software for quantitative measurement. In brief, a constant unit area was selected and average density of the total band area of the respective proteins in control and treated groups were measured and represented graphically

Statistical Analysis

The results were expressed in terms of mean± SEM (n=6). The data were subjected to one way analysis of variance (ANOVA) followed by Tukey’s test using GraphPad InStat 3 software to establish statistical significance (*p<0.05, **p< 0.01, ***p< 0.001).

We conclude that StnII/A10 gave exciting finding about the localization and the nature of the different lipid deposits in NPCderived cells that could improve the knowledge of lysosomal diseases.

Figure 4a: Western immunoblot analyses of intracellular apoptotic proteins.NNSS2 (1 mg kg-1 body weight) treated uterus and ovary. Protein from the total tissue lysate was subjected to SDS-PAGE and western immunoblot analysis was done using Caspase 3,9, Bax, BCL2, PARP, HSP70, HSP90, β-actin primary antibody. After primary antibody incubation, respective secondary antibodies were added and colour development was performed using NBT/BCIP mix. The relative intensity of each band was measured after normalization with the intensity of β-actin in a blot (shown below each western blot). Representative blots from three independent experiments gave identical results.UT: Uterus; OV: Ovary

Discussion

This present study was designed to isolate a bioactive factor from Naja naja shedded skin. In the present study, a small molecular weight crystalline peptide NNSS2 of 882.6 Dalton was isolated from Naja naja shedded skin. CD spectral analysis indicated NNSS2 is composed of β sheet random coils and α helix. NNSS2 is crystalline and is composed of β-sheeted structure, N-H bonding, scissoring, bending and double bonds. Six amino acids had been identified so far namely asparagine, aspartate, glutamine, glycine, phenylalanine and tryptophan from.

NNSS2 caused cessation of the estrous cycle at diestrous phase for five days when observed microscopically, with corresponding change in ovarian and uterine histology. NNSS2 caused loss of three distinct layers, uterine glands and luminal structure with formation of vacuolated structure (Figure 3B). NNSS2 produced constricted ovarian structure, follicular atresia, phase arrests, absence of granulosa cell lining (Figure 3D), indicating uterine and damage and may be the cause behind phase arrest. The histological findings of both ovary and uterus supported tissue damage suggesting anovulation and phase arrest at diestrous. Tissue damage that had taken place in the uterus and ovary might have occurred either by apoptosis or by necrosis. Hence, to further elucidate the death pathway, expression of intracellular apoptogenic proteins of ovarian and uterine tissues were studied. In both the ovary and uterus increased the expression of caspase 3 and caspase 9 and cleaved PARP with no change in caspase 8activities indicated involvement of intrinsic apoptotic pathway. PARP cleavage by caspase 3 is a considerable marker for apoptosis [8]. In the present study NNSS2 caused PARP cleavage indicating apoptosis through caspase 3 dependent pathway. No significant change in TNF-α level further confirmed absence of extrinsic pathway as TNF-α receptor is responsible for the activation of caspase 8 through the death receptor complex [9]. The intrinsic pathway of apoptosis gets activated by negative signal given by decreased level of progesterone and a positive signal from increasing expression of IL-1β, eventually activated the caspase dependent pathway [10]. This mitochondrial dependent pathway is regulated by BCL2 family of proteins which included proapoptotic protein like Bax and antiapoptotic protein like BCL2 by modifying mitochondrial membrane permeability. NNSS2 increased expression of proapoptotic protein Bax and decreased the expression of antiapoptotic protein BCL2, ultimately leading to the activation of effector molecule caspase 3. Activation of caspase 3 leadsto the proteolytic cleavage of PARP responsible for morphological and biochemical changes in apoptosis [11,12].

HSP70 and HSP90 are molecular chaperone proteins associated with intracellular stress and play a critical role in cytoprotection [13]. HSP70 blocks apoptosis by binding to Apaf-1, prevented the formation of apoptosomal complex further inhibiting caspase 3 induced proteolytic cleavage of PARP [14]. HSP90 another chaperone protein directly binds to Apaf-1 inhibited apoptosome complex formation [15]. In the present study NNSS2 down regulated the expression of both HSP70 and HSP90 indicating apoptosis induction, suggesting follicular atresia and estrous cycle arrest at diestrous phase.

In the serum NNSS2 significantly decreased progesterone (Table 1); progesterone secreted from the corpus luteum is associated with anti apoptotic activity and exerts direct effect on luteal action [16]. Other than antiapoptotic activity progesterone is also associated with granulosa cell development [17], steroidal bio synthesis and number of cell signalling activities and is also intricately associated with cytokine regulatory pathway [18,19]. Present study revealed that NNSS2 significantly increased serum IL-1β expression. It is a very well documented fact that increased expression of IL-1β is associated with the induction of apoptosis by the involvement of ICE which converts the pro enzyme in to its active form [20]. From the present study it was revealed that NNSS2 influenced the estrous cycle in female albino mice by causing cessation of the estrous cycle at diestrous phase for5 days.

Conclusion

NNSS2 caused anovulation hence it can lengthen a normal cycle by modulating the hormones, cytokines and intracellular apoptotic proteins. From the above findings it could be concluded that this study gave a novel insight into some of probable bioactive factors present in snake (N. naja) shed skin which remained unexplored until now.

Acknowledgements

We thankfully acknowledge University Grant Commission, New Delhi, India for partial financial assistance (Ref No: F 38-130 (SR), dated 19.12.2009 and we are thankful to the Department of Forests & Wild Life, Government of West Bengal, India (2105/WL/4R-1(PI- IX)) for kind permission of collection of the shed snake skin.